Brazing a stacked body with a screen

The invention claimed is: 1. A brazing method, comprising: forming at least one brazing sheet into a plurality of plates; stacking the plurality of plates to form a stacked body of a heat exchanger; housing the stacked body in a screen to cover and enclose a periphery of the stacked body; and brazing the stacked body under an atmosphere of inert gas without flux and bonding a portion of the plurality of plates that overlap each other; wherein: housing the stacked body in the screen includes forming an overlapping margin between the stacked body and a brim portion of the screen; at least 70% of a top face of the stacked body is disposed outside of the overlapping margin and defines a heat receiving surface area of the stacked body; the at least one brazing sheet includes at least three layers; the at least three layers includes a core material, a brazing material layer, and an intermediate layer; the at least three layers are cladded with an outermost layer being the brazing material layer; the intermediate layer is disposed on at least one face of the core material; the core material is composed of a first aluminum alloy including at least one of (i) 0.20 weight % to 1.0 weight % of Cu, (ii) 0.8 weight % to 1.8 weight % of Mn, and (iii) 0.25 weight % to 1.5 weight % of Mg; the intermediate layer is composed of a second aluminum alloy including 0.20 weight % or less of each of Si and Fe and 0.10 weight % or less of each of Cu, Mn, and Cr; the brazing material layer is composed of a third aluminum alloy including 10 weight % to 15 weight % of Si and 0.25 weight % to 1.5 weight % of Mg, the third aluminum alloy having a melting point of 575° C. or less according to a DSC method; at least one of the second aluminum alloy and the third aluminum alloy include 0.02 weight % to 0.25 weight % of Bi; and a fluid coefficient of the brazing material layer on a side on which the intermediate layer is disposed is, according to a drop type flow test, in a range of 0.40 to 0.60. 2. The brazing method according to claim 1 , wherein: the stacked body is housed in the screen prior to brazing and bonding the plurality of plates; and the screen has a vertical cross sectional partition shape. 3. The brazing method according to claim 1 , wherein housing the stacked body in the screen includes forming a minute gap between an inner wall face of the screen and a tip edge of the stacked body. 4. The brazing method according to claim 3 , wherein: the brim portion is disposed at a periphery of a top end portion of the screen; and housing the stacked body in the screen further includes forming a gap between the brim portion and the top face of the stacked body. 5. The brazing method according to claim 4 , wherein a dimension of the gap in a stacking direction of the stacked body is 5 mm or less. 6. The brazing method according to claim 3 , wherein a dimension of the minute gap perpendicular to a stacking direction of the stacked body is 0.5 mm to 5 mm. 7. The brazing method according to claim 6 , wherein the dimension of the minute gap is 2 mm or less. 8. The brazing method according to claim 1 , further comprising, before brazing, chemically cleaning at least one of the at least one brazing sheet and the plurality of plates using at least one of an acid aqueous solution and an alkali aqueous solution. 9. The brazing method according to claim 1 , further comprising projecting a projection material at at least one of the at least one brazing sheet and the plurality of plates before brazing. 10. The brazing method according to claim 1 , wherein the overlapping margin extends 5 mm or less from an outer periphery of the top face of the stacked body. 11. The brazing method according to claim 1 , wherein housing the stacked body in the screen further includes: arranging the stacked body and the screen on a base plate; and positioning the screen on the base plate using a locator disposed on the base plate. 12. The brazing method according to claim 1 , wherein: the second aluminum alloy includes at least 0.01 weight % of an element having a higher vapor pressure than Mg at 577° C.; and the element having the higher vapor pressure than Mg is Na. 13. The brazing method according to claim 1 , wherein the intermediate layer second aluminum alloy further includes at least 4.5 weight % of Zn. 14. A method of manufacturing a heat exchanger, comprising the brazing method of claim 5 . 15. The method according to claim 14 , wherein the heat exchanger is configured to cool at least one of a vehicle internal combustion engine and a transmission lubricating oil. 16. A heat exchanger manufacturing method, comprising: forming a plurality of brazing sheets into a plurality of plates; stacking the plurality of plates to form a stacked body; housing the stacked body in a screen having a cross sectional partition shape to cover and enclose a periphery of the stacked body; and brazing the stacked body in an atmosphere of inert gas without flux and boding a portion of the plurality of plates that overlap each other; wherein: housing the stacked body in the screen includes forming an overlapping margin between the stacked body and a brim portion of the screen; at least 70% of a top face of the stacked body is disposed outside of the overlapping margin and defines a heat receiving surface area of the stacked body; the plurality of brazing sheets each include at least three layers; the at least three layers includes a core material, a brazing material layer, and an intermediate layer; the at least three layers are cladded with an outermost layer being the brazing material layer; the intermediate layer is disposed on at least one face of the core material; the core material is composed of a first aluminum alloy including at least one of (i) 0.20 weight % to 1.0 weight % of Cu, (ii) 0.8 weight % to 1.8 weight % of Mn, and (iii) 0.25 weight % to 1.5 weight % of Mg; the intermediate layer is composed of a second aluminum alloy including 0.20 weight % or less of each of Si and Fe and 0.10 weight % or less of each of Cu, Mn, and Cr; the brazing material layer is composed of a third aluminum alloy including 10 weight % to 15 weight % of Si and 0.25 weight % to 1.5 weight % of Mg, the third aluminum alloy having a melting point of 575° C. or less according to a DSC method; at least one of the second aluminum alloy and the third aluminum alloy include 0.02 weight % to 0.25 weight % of Bi; and a fluid coefficient of the brazing material layer on a side on which the intermediate layer is disposed is, according to a drop type flow test, in a range of 0.40 to 0.60. 17. The heat exchanger manufacturing method of claim 16 , wherein housing the stacked body in the screen includes forming a minute gap between an inner wall face of the screen and a tip edge of the stacked body. 18. The heat exchanger manufacturing method of claim 17 , wherein: the brim portion is disposed at a top end portion of the screen; and housing the stacked body in the screen further includes forming a gap between a lower face of the brim portion and the top face of the stacked body. 19. The heat exchanger manufacturing method of claim 13 , wherein: at least one of the material first aluminum alloy, the second aluminum alloy, and the third aluminum alloy further includes at least 0.01 weight % of an element having a higher vapor pressure than Mg at 577° C.; and the element having the higher vapor pressure than Mg is Na. 20. A brazing method, comprising: